Calculating machine for effecting division



y 11, 1939- J. w. BRYCE ET AL 2 20 CALCULATING MACHINE FOR EFFECTING DIVISION v Filed June 29, 1954 11 Sheets-Sheet 1 CALCULATING MACHINE FOR EFFECTING DIVISION T Mae/"41min l INVENTQR$ 597 6:, 12 w ATTORNEYS July 11, 1939. J. w. BRYCE AL CALCULATING MACHINE FOR EFFECTING DIVISION Filed June 29, 1934 -11 Sheets-She'etS A TTORNEYSI.

July 11, 1939. J. w. BRYCE ET AL CALCULATING MACHINE FOR EFFECTING DIVISION Filed June 29,

1934 ll Sheets-Sheet 4 0. 0w On 0* 0m 0m 0s 0m Om INVEN 0 Z," en...- BY Mop/Q0" rw .ATTORNEYS.

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CALCULATING MACHINE FOR EFFECTING DIVISION July-11, 1939.

July 1939- J. w. BRYCE EFAL CALCULATING MACHINE FOR EFFECTING DIVISION Filed June 29, 1954 ll Sheets-Sheet 8 m #7112 If a? AT TURN-2Y5.

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July 11 1939- J. w. BRYCE ET AL I CALCULATING MACHINE FOR EFFECTING DIVISION 11 Sheets-She 9 Filed June 29, 1934 1 VE TORS m w ATTORNEYS.

July 11, 1939.

CALCULATING MACHINE FOR EFFECTING DIVISION .9 27 BACK arzsw J. w. BRYCE y ET AL Fi leq June 29, 1954 11 Sheets-Sheet 1O INVIENTORS A TTORNEYS.

Patented July ii, N339 UNITED STATES PATENT caries:

CALCULATING MACHINE FOR. FF'FEC'I'FEJG DIVISION J ames W. Bryce, Bloomfield. N. 3., and Arthur H.

Dickinson, Brooklyn. N. Y., :issignoz's to International Business Machines Corporation,

New York, N. Y., a corporation of New York 1934, Serial 1335576 Application June 29.

23 Claims.

the customary procedure is to add back the di- 7 visor once into the dividend accumulator, thereafter the divisor is shifted over one place relatively t the right and the above subtraction operation is repeated. A quotient counter is customarily provided to keep count of the number of subtracting operations in each denominational order and this subtracting counter also subtracts 1 when the divisor amount is'reintroduced into the dividend accumulator. This process pro ceeds tor the various denominational orders of the dividend until the capacity of the machine is reached or until as many places are set up in the quotient counter as are desired. If an amount then remains in the dividend accumulater this is the remainder. 1

Various proposals have been made to shorten up these operations, but none of them materially speed up the operation.

According to the present invention upon going back of zero in lieu of reintroducing the divisor into the dividend accumulator, then efiecting a column shift and then subtracting the divisor from the dividend accumulator a difierent course oi procedure is followed. Upon going back of zero, column shift is effected and thereupon there is introduced into the dividend accumulator an amount which is nine-tenths of the divisor.' Bylntroducing nine-tenths oi the divisor in shifted over columnar relation the efiect is exactly the same as adding back the divisor and then shifting over and subtracting the divisor, i. e., in one cycle the same numerical result is obtained as heretofore required two cycles. This will be clear from the following table which shows the old method in contrast to the new method for a typical computation of 57635 divided by 12.

Back of zero Add hack l2 Shift Back oi zero Add back 12 Sh i Back of zero Add back 12 Shiit Back of zero Add back 3?.

From the foreg Problem Combined 000035 eycie---- oing comparative table, it will be seen that the new method saves one com plete machine cyclerevery time there issazgcing -back of zero operation requirml.

' In .theioregoing table the short vertical lines under Dividend represent the columnar positions According to the preierred. .embodiment oiithe oiitl'ie dividend accumulator. The vertical lines invention, the present machinezeiiccts under Divisor indicate the columnar positions oi tion bycomplem'ental addition inplse'emi efleetthe divisor entry device. .The vertical lines under s in; it by direct subtraction. Thus sn illus- .9"Divisorindicate the columnar positions at the trative computation'would betas divisor e'nti'y receiving device. The table also mas. shows the marmer in which the .9 divisor is 'iormed, that is, it is iormed by addins to the mess divisor oillthelos true complement thereoi in 10 L .shiitedover columnar position. In the ioregoing oasis v tableithe underlined numerals to the leit india a catethe uotient, that is progressively created. Pram mm m muted prime Qsindicated thin -9"-indicate that 1 mm the dividend accumulator has gone back oi zero 35 Y 5 mi i i g m the M v and whenever V the dividend accumulator ,goes a According the 0! zero .9 0f the Him tient counter is dispensed withentinlysndithe dividend accumulator in shiited columnar rela- According to the present invention provision is made iorrelatively evaluating the dividend and putation according to a pro-selected number oi quotientiplaoes'jwhich may he set up in advance by the operator. The computation willbe car-' riedout to the pre-selected number oi places or one less than the pre-selected number-edepending upon whether or not the divisor goes into the dividend in the iirstplacef The present invention'fias ior one oi its obiects the provision oi an improved automatic division' machine wherein quotients and remaindcrsm'ay be obtained automatically by the operation oi the machine. 7 w i A further object oi the present invention reas idea in the provision oi arecord controlled division machine in which the divisorjiand 11111 dend may be automatically read irom a record, automatically divided by the operation oi the machine and the result or results automatically. recorded.

"A iurther object oi the present invention resides in the provision oi result recording means his recording the result or results upon the I record iromiwhich the divisor and dividend yore 4s A iurther object at the present invention resides. in the provision oi a machine ior providing a recorded statement which consists oi divi-' dend. divisor, quotient and remainder. so

A iurther object oi the present invention resides in the provision oi means ior speeding up the operation oi a division machine by providing novel means ior handling hack oi-zero operations to the general end that extra machine as cyclheretoiore attendant upon back oi zero 0M may be eliminated.

A iurther object of the present invention resides in the provision oi means enabling the machine to utilize the dividend counter or entry I device as the quotient counter or entry device thereh eliminating the necessity oi a special quotient counter.

A inrther object at the present invention residesin the provision of an automatically as crating division machine which will operate and compute division problems automatically withoutmanual intervention,

A further object oi the present invention resides in the provision oi improved means ion-m controlling the operation oi the division machine ior computing a quotient to a'pre-selected number oi quotient places.

A further object oi the present invention 'resides in the provision oi improved means ior cor- 1g quotient is entered into theleithsnd partoi-ithe dividend accumulator as the at the beginning oi the computationwere occuas pied by the dividend itseli. The dividend accumulator thus assumes a dual role. It starts out as a dividend accumulator alone and :asthe computation proceeds, parts oi it become the quotient counter andiotherparts constitute a. remainder device.

' The steps vmich the machine .periormsin aparticular computation in dividing5l635by 12' andthemannerinwhichthcsuccessivedigits appear will be clear from theioilowins table. v Dividend mm:

liiiiliiiiii oossoo I A .01112: "ioaoo aooosstoo o" 'sssoo' v relating the location of result recording auto- .matically according to the relative evaluation of the dividend and divisor and automatically the operation of the machine.

a A further object of the present inventim resides in the provision of improved controls for division machines to enable the machineto function in a more speedy manner than heretofore and to provide for diverse machine operations 10 which are involved in divisional computations l I with minimum of operator: attention or A further object of the present invention resides in the provision of 'a division machine which will sucoessivelyperform a succession of separate division problems without manual intervention and thereby effect division of aplurality of separate and distinct computations more rapidly than heretofore possible.

A further object of the present invention resides in the provision of an automatic machine with improved controls to automatically determine the going back of zero in the machine; and for automatically controlling subsequent ma- J chine operationaaccordingly without the manual intervention of the operator.

Generally stated the objects of the present in vsnticn comprise the improvement of division machines in general; the improvement of divis-- ion machines to the general and that operations may be effected automaticallyby machine operations that heretofore required the attention of the operator; the improvement of division machines so that division results may be recorded automatically with one result recorded after another automatically with all computations and recording operations effected without manual intervention; the improvement of division ma- ,chines to the general and that the machine may operate without the loss of time which heretofore existedin such machines; and to the general end that a machine be provided accomplishingfunctions and results not heretofore attainable.

all of which will be more fully set forth in the u accompanying specification and drawings of one and a preferred embodiment of the invention.

-. Furtherandotherobiectsofthe present in ".vention will be hereinafter set forth'in the aoff.- [company ns specification and g. in the drawings which show by way of fillustra- .1=

-tion a prefenedemhodiment 'thereofandwhatwe nowoonsidertobethebest mode in which we have contemplated of applyf- -Z ing that'principle. embodiments of the z' invention employing the same orliiequivalent; principiemaybeusedandatructuralchanges- .madeasdesired by thoseskilledin'theart without departing from the present invention and within the spirit ofthe appended I "machine; l I

q rm. to. so, as, oand re, arranged vertically in the order. show'thc-f circuit diagram of the machine;

diagram of the machine;

Fig. 5 shows a detail of'the Twas luc switching mechanism and [one of the entry receiving devices which origi-- tient and remainder results upon the record 10 card. Figs. 7 and 8 show in a somewhat more abbreviated mannerthan shown in Fig. 8, other computations performed by the machine. Fig. 7 shows an'operation where there is no shift of the divisor and dividend upon entry, in which case. according-to the law of the present machine, there is a back shift of the quotient of threeplaces upon recordingrthe result. Fig. 8

'- shows another computation wherein there is an, entry shift of the divisor and dividend upon 90 entryand a corelated back shift upon reading vout the quotient.

-.-Before describing the construction of =chine to which the present invention is shownapplied. the general prlnciplesunderwhich the a machine operates and'the'qenerdlmnde ofop-l eration will be set forth. According to the present invention the ma-' chine carriesoutdivision in the following mm her. The dlvidend' and-divisor are first entered into the there'being a double entry 0'! the divisor, i. e.,,the divisoris entered into each of two separate entry receiving devices. diately following the cycle in which the dividend and the divisor are entered into themachine 3 .there is a further-machine cycle in which divisor is subtracted-from itself in shifted over columnar relation displaced one place to the right. In other-words; one-tenth of the divisor is subtracted from the divisor. The result is that nine-tenths of the divisor becomes set up upon nally received the divisor itself. Concurrently with this operation in which the one-tenth of the divisor is subtracted from a divisor entry the i divisor amount is also subtracted from the divi dend. subtraction being 'eflected in the highest order or orders places of the dividend. In pass- ;:.ing it may be mentioned that the dividend is en I I tered so sate-always be introduced as far as poo-f sible to the left "in the-dividend accumulator but leaving two ordersto the left of the dividend.

"This is selectively, controlled automatically by V the machine itself. The divisor is likewise entered in a similar position in the divisor entry 55 receiving devices. After the first subtraction is completed, further subtracting operations are performed and this subtracting process is rethroushi.or- -back*of'sero'is determined by a s appearing: upon one of the left handwheels of' dividend entry receiving device, appearing in to themachine that a column shift action is to occur and that the nine-tenths divisor amount} is to beautomatically introduced into the divi;

.dend accumulator in theshifted over positiontherein. [This operation is .once'and F thereafter there are further automatic subtract h H yingoperationsperfonnedusingtheoriginaldiu Figs.6,'land8areviews"showingtypicalcoInvisor amount. 1 1g agparticular wheel of the dividend sccumulags tor; is sensedior the presenceof 1f land when a 9 appears therein it indicates All of the foregoing Operations will be found to introduce into the dividend accumulator the amount of the quotient. It may be explained that the quotient entries in the dividend accumulator are obtained by virtue of carry-over actions in the accumulator itself.

When the computation has been extended to the predetermined extent and if the dividend accumulator has gone back of zero the machine will not re-introduce the nine-tenths divisor amount into the dividend accumulator and in lieu thereof will add back automatically the original divisor amount. This will then set up in the dividend accumulator in the proper columns thereof the amount of the remainder and it will also serve to bring the quotient to the proper amount.

The machine continues to perform its operations until the desired number of places in the quotient are obtained and thereafter the-quotient and the remainder if any, is recorded back on the record card from which the original factor data was derived.

According to the present invention provision is made for recording the quotient and the remainder if any, upon a record card as stated above. Provision is also made for recording this same data upon a record sheet by printing operations.

The calculating machine to which the present improvement is applied, so far as numerous of the various units and the manner of drive is concerned, is substantially the same as the machine shown and described in United States patents to Cunningham, No. 1,933,714 and Oldenboom, No. 1,944,665 to which reference may be had for a fuller description of the general operation of various units and the manner of drive.

In lieu of providing a direct drive for the contact roll 81 (Fig. 1a), a creeping drive is provided of the type shown and described in the United States application of George F. Daly, Serial No. 643,663, filed November 21, 1932. The creeping drive includes supplemental gearing 81a, Bib, 81.0 and Bid for driving the contact roll 81 with a creeping movement, The machine includes an entry receiving device DD for the dividend (Fig. 1). There is also provided an entry receiving device DR to receive the dividend itself and an entry receiving device .9DR for retaining a set up of nine-tenths of the divisor. These various entry receiving devices are accumulators and are driven in the same manner as correspondingly located units in the Cunningham patent above referred to. There is also a reset drive generally similar to that shown in the Cunningham patent.

In addition to the foregoing entry receiving devices a printing section is provided, indicated at PR (Fig. l) This printing section is similar to the printing section or unit of a conventional printing tabulator and particularly is like the printing mechanism shown and described in the copending application of George F. Daly, Serial No. 704,768, filed December 30, 1933. In explanation it may be stated that in lieu of providing two cams, a

list cam and a total print cam, there is a common drive and the printing mechanism is normally out of operation and selectively called into operation by means of a one-revolution clutch shown at II in Fig. 1. This one-revolution clutch is called into operation upon enerfization of one-revolution clutch magnet ii (Fig. l).

The machine also includes a column shift and control relay section CS and CR (Fig. 1a). The machine includes three impulse emitters l2, l3

and Il (Pig. 1) and two impulse distributors l5 and it (see Fig. l).

In the present machiric there are fifteen PC cam contacts which are designated FG-i i015 inclusive on Fig. 1a, which are driven from the card feed drive in the indicated manner. The machine includes cam contacts CCI to l2 inclusive (Fig. 1) which are driven from accumulator drive shaft in the indicated manner. The DD accumulator resetting devices control three sets of contacts, one group is designated I1 and comprises a pair of contacts which are adapted to be opened upon reset. Another group is designated l8 and comprises a pair of contacts which are adapted to be opened upon reset The third group of contacts are three-blade contacts designated l9 and 20. Contacts I! are adapted to be opened upon reset and contacts 20 close upon reset.

Referring now to Fig. 2, the card handling and sensing section of the machine is generally the same as in the Cunningham patent above referred to. The usual readout or sensing brushes are shown and designated at 2!. A supplemental set of pre-sensing or advance sensing brushes are also shown which are indicated at 22. This set of brushes comprises a complete set of brushes which extend completely across the record card field. There are also provided the card lever con tacts 23. Supplemental card lever contacts 24 are likewise provided which are set to come into action in advance of the other regular card lever contacts 23.

Complete details of the punch are not herein shown as they are substantially the same as in the r.

punch described in the Cunningham and Oldenboom patents. A fragment of the punch is shown on Fig. la in proximity to the card R in the entering section of the punch. The rectangle indicates the punching mechanism of the aforesaid patents.

Readouts The various entry receivihg devices have readouts associated therewith. The DR entry receiving device has a readout of so-called inverting type as shown on the circuit diagram (Fig. 3a). With this Iorm of readout it is possible to read out either the true number standing in the entry receiving device or the true complement thereof. The nine-tenths DR. entry receiving device is provided with a straight or simple form of readout. The DD dividend accumulator is provided with a double form of straight readout. This double readout is provided so that one section can be utilized to read out to the punch and the other section to readout to the printing mecha nism, The DD accumulator also has a supplemental superimposed readout which is used for control purposes, This is driven from the regular double readout by suitable gearing. Full details of such double or superimposed readout is shown in the copending application of James W. Bryce, Serial No. 654,619, filed February 1, 1933.

Quotient place mechanism In addition to the readout structures the ma chine is provided with a quotient place mechanism which is generally in the-nature of a readout structure. A portion of this quotient place switching mechanism is shown in Fig. 5. As here shown it comprises a series of brush assemblies generally designated 62 fast to, but individually insulated from a shaft 83 and concurrently positioned by a knurled wheel 64 fast to the shaft Ill) 43. The knurled wheel may be conveniently provided'with a pointer 64a cooperating with anindex 64b. Each brush assembly 62 cooperates with a readout commutator shown "in Fig. 5 comprising segment spots 62a and with an associated common segment '65. Each readout commutator has eight readout or segment spots 62a corresponding to eight columns, the maximum number of quotient places which may be obtained with the present machine.

In the instant machine there are thirty-three commutator sections, only three of which are shown in Fig. 5, the remainder are shown in the circuit diagram. It will'be understood that the brush assemblies are concurrently positioned and they may be set to stand on any one of the segment spots from 1 to 8 inclusive. On the index 64b the numbering is doubled because of the dual brush arrangement. In positioning this quotient place mechanism the knurled wheel 64 is turned up to the number of maximum places desired in the quotient. I

Operation Before describing the circuit diagram of the machine the general mode of operation of the machine will be briefly explained. It will be assumed that the present machine is intended to handle dividend entries of a maximum of eight columns and divisor entries of a maximum of four columns. Obviously the machine may have a greater or less capacity. Upon a card entering the sensing section of the machine the pre-sens m8 brushes 2! sense the divisor and dividend fields of the card and selectively control the entry of the divisor and the dividend in the following manner.

The divisor'is entered as far to the left as possible in both of the divisor entry receiving tievices. The dividend is entered as far to the left as possible in a selective manner, but insuch a manner as to leave two orders to the left of the entered dividend. In short, the pro-sensing brushes feel for the highest order significant digit column of both the divisor and dividend and control the entry into the respective entry receiving devices accordingly in the manner indicated. 1

' Circuit diagram and dividend are in the supply magazine 24' ot the card handling section of the machine (sec.

punch driving motor 11-4. Rotation of .the main driving motor M puts into operation the A. C.-D. C. generator 82 (Figs. 1, 3a, and 8c). The A. C. end of this generator supplies current tobusllandto groundandtheD.C.endof the generator supplies current to buses 34 and I4 'Ihestartkeyisnow depressedtoclosestart key contacts 04 (Fig. 8c) and to complete a circuit from the ll side of the D. C. line through relay coil 0. relay contacts (3-! now closed, cam contacts FC-l, to the 34 side of the D. 0. line. A stick circuit is established through relay contacts 0-2, cam contacts FC2 now closed. Energiaa-' O-l now closed, through relay contacts M--2 now in the position shown, through the punch controlled contacts-P--l now closed and back to line 34. As in previous machines the start key must be kept depressed for the first four countercycles in starting up a-run or alternatively it may be depressed and released and again depressed. Startingoperations are prevented until the feed rack of the punch is inproper right hand position, this being provided for by contacts P--i.

Before starting up the machine the proper plug' connections will be made at plug board 40 (see Fig. 3a) for the entry of the divisor and dividend into their respective entry. receiving devices. Other plug connections will be made at plug board 4! to properly plug up the advance or presensing brushes 22 to certaincontrolling relays. The divisor field relays are designated and the dividend field relays are designated 43. The related contacts are shown at 42c and 43a, there being a single contact pair controlled by each relay coil. When a contact 420, for example, is closed', it serves to energize a related relay coil 44 and similarly the closure of a contact pair 430 serves to energize a related coil 45. Coils 45 and 44 have associated therewith transfer contacts designated 45a and 44a. The function of these transfer contacts is thiswhen a transfer contact for example 4511 pertaining to a given denominational order is closed, the closure of such transfer contact will serve to energize all of the coils 45 to the right or in relatively lower denominational orders. Transfer contacts 440. similarly control the energization of coils 44 pertaining to relatively lower denominational orders. Coils 45 and 44 likewise control stick contacts 451) and 44b and such stick contacts when closed establish a stick circuit from the 34 side of the DC. line through any one or more of the coils 4i and 44' and back to the SI side'of the D. C. line through cam contacts I'O-I.

. It may be explained and as shown on the timing diagram that coils 4 and 44 become energised late in the card feed cycle when a card is passing the advance sensing brushes-22 (Fig. 2).

According to the selective energization of coils 44 and 44 in the manner above explained, there is a selected directed entry of the dividend and divisor into their corresponding entry retaining devices. This is provided for by pyramidical contacts 44c and 440. Such contacts, according to their selective closure', direct the entry of the dividend into the dividend accumulator sothat it Pig. 2). To start the machine in operation switch 44 (Fig. 3c) is first closedto supply rent for the main driving motor M and for the always enters leaving two clear columns. to the -extremelefrin. the dividend accumulator.

. Similarly. pyramidical contacts 44c according to their selective closure, selectively direct the entry of the divisor into each of its entry receivin devices so it goes'into the extreme left hand columns of eachentry receiving uma; it may be stated that the pickupcircnit for the coils 42 and 43 h completed through the following path: referring'to Pig. 48, through thecard lever contacts 24, through the cam contacts I'D-4. through the distributor N. to the common contact plate 44, thence via the brushes 22, through the plug connections at plug board 4 i, through the coils 42 and 4,3 and back to line 44.

At the end of the first card feed cycle, the first card will havebeenadvanoedtoapointinwhich it is about to be read by the sensing brushes 2!.

During the second card feed cycle the card trav erses the brushes ll-and the dividend is entered in the dividend accumulator and divisorsmountsare entered into their respective entry de-- vices. The divisorit will be understood in this cycle, is entered into both the DR and .9DR entry receiving devices. At the end of the first card feeding cycle the card lever contacts 23 (Fig. 3e) will be closed by the card, causing energization of relay coil H (Fig. 3e) and causing relay contacts H-l (Fig. 3a) to close. As the second card feed cycle ensues, the card is carried past the brushes 2| and the dividend accumulator DD receives the dividend entry and the divisor entry receiving devices DR, and .9DR receive their entries.

Before tracing the entry circuits, it may be explained that just after the card feed cycle is initiated, cam contacts FC--4 (Fig. 3e) close to energize relay coil J. With relay coil J energized, contacts J-i to 8 (Fig. 3b) and contacts J--9 (Fig. 3a) will become closed. The entry circuits for the dividend and divisor will now be traced. Current flows from the A. C. line 33 (Fig. 3a) through relay contacts H-l now closed, through relay contacts J9 now closed, through impulse distributor l5 to the card transfer and contact roll 81, thence through the brushes 2|, pertaining to the divisor, through plug connections at plug board 40, through the pyramidical contacts 0, to the divisor entry control magnets 41 and 48. The magnets 41 are in the DR entry receiving device and the magnets 48 are in the .9DR entry receiving device. The circuit to the magnets 48 is through the three-blade multi-contacts iCR-l to 5 which are in the position shown at the time the first entry is made. The entry circuits to the DD accumulator are through the path previously traced to contact roll 81, through the brushes 2i pertaining to the dividend, through plug connections at plug board 40, through the pyramidical contacts 450,. through relay contacts J-I to 8 inclusive (Fig. 3b) which are closed by the energization of relay coil J and to entry control magnets 49 pertaining to the dividend accumulator.

It may be explained that prior to the record card passing the regular sensing brushes 2|, the printing unit must be called into operation in order that the amount of the dividend and the amount of the divisor can be printed on the strip in the printing device.

The printing unit is called into operation at the proper time in the following manner.

Referring to Fig. 3e, a circuit is completed from the 35 side of the line through the print section clutch magnet I0, auxiliary stop key contacts 39a, through relay contacts H|, through relay contacts C-3, through cam contacts FCI3, to the 34 side of the D. C. line. The printing section is accordingly in operation at the time the card is traversing the regular reading brushes 2|. According to the perforations in the card, the brush circuits are completed through wires in cables 50 and 5| (Figs. 3a to 3d) to sockets at the print section plug board 52, via plug connections at this plug board to the print magnets 53 which are allotted for printing the dividend and divisor. The printing unit obviously operates in the usual way to print the dividend and divisor.

The hand initiating control is cut out after the operations have been properly started. This is effected in the following manner. At the beginning of the second card feed cycle the closure 0! cam contacts FC5 (Fig. 3e) will cause relay coil G to become energized. Current flows from line 35, through relay coil G, throughcam contacts FC-5, through thecard lever contacts 23 now closed and back to the other side of the line 34. The energization of relay coil G will shift relay ammao contacts G--l to reverse position interrupting the circuit to the start key contacts 30, but maintaining the circuit to cam contacts FC--l. The energization of relay coil G will also close relay contacts G-2 and establish a stick circuit for relay coils G and H either through the FC-I cam contacts or the card lever contacts 23. It may be explained that the making time of cam contacts FC--l overlaps the time when the card lever contacts 23 open between cards.

It has been previously explained how the selective closure of pyramidical contacts 450 and c (Fig. 3a) selectively direct the entry of the dividend in the dividend accumulator and divisor into its respective entry receiving devices. It will be understood that after the entries have been made into these devices that a further card pertaining to a succeeding computation will follow and pass the advance sensing brushes 22. Before such following card passes the brushes, provision mustbe made for breaking down-the set-up which controls pyramidical contacts 450 and 0, but before breaking down such set-up a retained set-up must be made corresponding to the previous set up of 45c and c for controlling the subsequent reading out operations for recording result data pertaining to the computations related to the card which has been previously sensed. This retained set-up is provided for in the following manner. Relay coils 45 and M (Fig. 3a) in addition to controlling the contacts previously referred to, control supplemental contacts 45d and d (Fig. 30). Before cam contacts FC-1 (Fig. 3a) open to de-energize relay coils 45 and M, cam contacts FC-ll (Fig. 3a) will close to energize relay coil A. The energization of relay coil A effects closure of relay contacts A-l to In (Fig. 3c) and accordingly when cam contacts FC-l5 close, circuits are provided through the now closed'contacts A-l to ill to such of the contacts 45d and d which have become closed to thereby selectively energize coils 55 and 54. Such coils 55 and 54 have stick contacts 55a. and 55a associated therewith and such stick contacts retain coils 55 and 54 energized after FC-i5 and relay contacts A-l to ll open. The stick circuit from the! and 54a contacts is through a circuit extending through the DD dividend accumulator reset contacts I! and back to line 34.

It will be understood by the foregoing operation that the set-up which was previously on coils 45 and 44 is now set up on coils 55 and 54 (Fig. 3c). The machine is now in a condition in which the initial stages of division by subtraction can be carried out. Such operations are automatically initiated in the following manner.

Referring to Fig. 3e, since relay contacts H 4 are already closed by the energizatlon of relay coil Hin the manner previously explained, 'at'the' time cam contacts FG-Il close, a circuit is completed from the 35 side of the 13.0. line through relay coil M. The energization oi relay coil M closes contacts M-I to provide a stick circuit for relay coil M. This stick circuit a completed 6Q tacts I! now closed. At the time a circuit is completed to M to eflect its energization cam conf through the DD dividend accumulator reset contacts FCII close to complete a circuit to ever;

gize relay coil N. Closure o! relay coil N causes-a closure of stick contacts N-i, the stick circuit.

being completed back to the other aided the line through the normally closed contacts (1 -2. wi h the energization of relay coil M, relay M-I shirt to reverse position from that shown.

The shift of these contacts M4 willjin-a hianii coil i-CR. Energization of l-CR will effect shift of relay contacts iCR-i to (Fig. 3a) to reverse position from that shown. With relay contacts |CRr-l to 5 shifted and with relay contacts W-Z closed in the position shown,'current will be supplied to the emitter l2 and with emitter I! in operation, impulses will be emitted to the inverting readout associated with the DR entry receiving device designated DRIV on the wiring 29 diagram, out via the group of lines generally designated 58, via lines 59, through the'now shifted iCR-i to 5 contacts to the 48 control magnets pertaining to the .9DR entry receiving device.

It will be understood that with contacts ICR-i to I shifted the entry will be made in this entry receiving device in orders each of which is relatively one order lower than heretofore, and that the complement of the divisor amount will be added into this entry device in such columnar .'io orders. There will thereupon appear in such entry receiving device a set up of nine-tenths of the divisor amount. As explained before during this set up of nine-tenths of the divisor there is a concurrent subtracting operation to diminish the amount in the dividend accumulator by the amount of the divisor.

Cycle controller and column shift control The cycle controller and column shift control 4n of the present machine has the following functions. It correlates the dividend diminishing operations for each quotient place causing the machine to continue to subtract by complemental addition until the dividend accumulator goes back of zero. The cycle controller is then apprised of this fact by the sensing of a 9 in a particular column of the dividend accumulaton It then controls the modification of machine operations to cause the introduction of a correcting 50 factor of nine-tenths of the divisor into the dividend accumulator. While the nine-tenths divisor value entry in the dividend accumulator is effected following .column shift the wiring from the nine-tenths readout device to the dividend accus; mulator is such that the nine-tenths divisor value is added in the same order as the complement was entered tocause an overdraft. The sensing.

,-control for the back of new 9 is then aiitinnatical-. I pi-lily shifted over one colu'mnto the right and this m shifting is effected undcr' the control of the cycle controller. If-no'l'back of Inero .9 is immediately obtained upon the entry of the correcting amount into the dividend accumulator, the. dividend diof the-cycle'oontroller-in the same columnar re- .until back of aero liasensed; If upon entry 'ofthc correct-v ing new hack of new 9 condition is immedfr miniahing operations continue under the control .lation'as that used for-the oormeting entry.

ment.of the dfvilorl-f dead accumulator ately'produdcd the'cyele controller so" controls the;

' the isotonic-again inpetition and; ccntroifisgagain shifted.

circuit-diagram: thereby interrupting-ti: l rcur. "to .DDB. entry control magnets is and Ipre dated entry :Th' emitter ing device'apprises the machine that no further quotient places are to be obtained. Thereupon the cycle controller functions to cause the automatic adding back of the divisor amount itself in the same columnar relation with respect to the 5 accumulator as was used for the last diminishing operation. Accordingly the cycle controller controls the columnar relation of entries into the dividend accumulator. It controls the position of sensing the back of zero 9, shifting the position of m the 9 progressively to the right as quotient places are obtained. It controls the introduction selectively of either the complement of the divisor, nine-tenths of the divisor or the divisor itself into the dividend accumulator.

Before explaining how the concurrent subtracting operation is effected, it may be mentioned that there is a cycle and column shift control associated with the supplementary readout of the dividend accumulator for the purpose of go controlling the columns in which entries for diminishing the dividend are to be introduced into the dividend accumulator and for controlling the number of cycles for such diminishing operations. This cycle and column shift controller is controlled from the supplementary readout section of the dividend accumulator designated DDRO--2 on the circuit diagram (Fig. 3b). The column shift and cycle controller is biased so that upon the first operation the entry of the complement of so the amount of the divisor will be introduced into the dividend accumulator in the most extreme left hand positions thereof in which entries are standing. This is provided for by transfer contacts i-Y-l which in starting condition are in .15 the position shown. With these contacts in the position shown, upon closure of cam contacts CC5 (Fig. 3b) and upon closure of relay contacts N-! which is brought about by the energization of relay coil N in the manner previously explained, current supply is afforded for column shift relay coil 08a. The energization of column shift relay coil CSa. closes the related column shift contacts 08a and accordingly the complemental impulses related to the amount of the divisor will flow through the DRIV readout through the lines generally designated 58, through the 2CR| to I contacts now in the po sitlon shownjthrough the group of lines generally designated I. through the column shift relay contacts C841 and over to the entry control magnets 4| pertaining to the DD accumulator. Accordingly the complement of the amount of the divisor will beintroduced into the DD accumu lator. 65

Concurrently with the introduction of the first complement of the divisor into the dividend aceumulator. a 9 is entered in the column of the dividend accumulate! next to the leftof the one receiving the entry. Le. the furthest left hand order of this accumulator; This is provided for by a circuit tracedf'ls follows. Through relay contacts 11-4 (Fig."3b) cam contacts 1 0-5. to the last entry control magnet of the group totheleftandback'mg'rormd. on

Upon completion of firstgoperation in which the .9 divisoriefcreated and jthc comple "'itroduced into em mummies-n is I willshiftahack "totho' position entfng change ct-thciaet-up 'ofthe' reef,-

to emit impulses over the circuits just traced, via 58, 60, etc., to the entry control magnets 49. The amount standing in the DD accumulator will be accordingly diminished by progressive subtracting operations which are performed by complemental addition until the order wheel pertaining to the highest order dividend column receiving an entry from the DRIV readout stands at 9. With this wheel standing at 9, a circuit will be completed through relay contacts N! (Fig. 3b). cam contacts CC-4, through the l-Y2 transfer contacts, through a IV relay coil, through the brush of the DDRO2 readout which is now standing at 9 and out via return line if, to D. C. line Ill. The coil IV being thus energized, it is held energized for a short time by stick contacts lV-l, the return circuit being via cam contacts CC-I. The energization of coil IV effects closure of pick-up contacts IV2 and a circuit will be completed from the II side of the line through relay contacts N-2, cam contacts CC4, through relay contacts R-2 now closed, through relay contacts lV-I now closed to energize relay coil IY. The energization of relay coil I? will shift transfer contacts lY-l and IY2 to reverse position from that shown. After relay coil IY has become energized, relay coil IV is de-energized.

The foregoing operations take place when the dividend accumulator goes back to zero. With the dividend accumulator'back of zero it will be understood from the preceding general description that the operation is to interrupt the introduction of complements of the dividend into the dividend accumulator and to introduce therein nine-tenths of the divisor in a shifted over columnar relation therein. The energization of IV will have also closed relay contacts lV--l (Fig. 3e) and accordingly with contacts lV-J closed when cam contacts CC-i close, relay coil W will be energized. A stick circuit will be provided for relay coil W though stick contacts W-| and cam contacts CC|. With relay coil W energized (see Fig. 3e) relay contacts W-2 (Fig. 3a) and W-3 (Fig. 3a) will be shifted to reverse position from that shown. The energization of relay coil W will also close relay contacts W-l (Fig. 3b).

Upon the next cycle, upon closure of CC! several operations take place concurrently. The column shift relay coil CS1) is energized, relay contacts lY-l being already shifted to reverse position from that shown in the diagram and relay contacts 2Y--i being in the position shown. With CSb energized, the corresponding column shift contacts CSb' will be closed. With relay coil W energized, contacts W-l will be closed and at the proper time in the cycle relay coil 2 '-CR, will be energized to cause the shift of relay contacts 2CR-l to 5 (Fig. 3a) to reverse position from that shown. With such contacts 2CR-l to 6 in shifted position and with the emitter II in operation and receiving current through contacts W2 now in shifted position,

' impulses will be emitted through emitter l3. via

cable 62, through the .9DRRO readout and ninetenths of the amount of the divisor will be read out from the .9DR entry receiving device and flow through the 2CRI to 5 contacts now in shifted position via the line 50 (Fig. 3b), through the column shift relay contacts 08b and over to the entry control magnets 49 in a shifted over columnarrelation therein provided for by the 'CSb"contacts. This will introduce nine-tenths 1 of the amount of the divisor into the dividend acaim cumulator. The effect of this is the same as adding in the amount of the divisor and again subtracting it in shifted over columnar relation in the dividend accumulator. After this operation is completed there is again a sensing of the dividend accumulator to determine whether or not the accumulator has again gone back of zero and if the accumulator has not gone back of zero a zero will appear to the left of the previously diminished dividend amount. Under these conditions the machine will then proceed to reintroduce the complement of the divisor into the dividend accumulator. This operation will occur by reason of the fact that relay coil W (Fig. 3e) becomes de-energized upon the opening of the stick circuit by cam contacts 00-1 and with relay coil W de-energized contacts W! and W-l (Fig. 3a) shift back to the position shown in the diagram. Relay coil 2-CR. likewise receives no current impulse at the time cam contacts CC-S close and accordingly contacts 2--CR-| to I assume the position shown in the diagram which is the reverse of the position which they previously assumed. Accordingly,-

there is a readout from the divisor entry receiving device through the inverting top readout section and the complement of the divisor is introduced into the dividend accumulator in proper columnar relation therein. This operation continues until a 9 appears in the dividend accumulator to the left of the diminished dividend. When such 9 appears, relay coil 2V becomes energized. There is a closure of stick contacts 2V--l and contacts 2V2 close. Relay coil IY becomes energized, stick contacts 2Y--I close, transfer contacts 2Y-2 shift and transfer contacts 2Y-l shift to transfer the column shift control to the CS0 coil, etc.

It will be unnecessary to trace the further operations.

counter The manner in which the quotient amount becomes set up in the dividend accumulator can best be understood by referring to the typical computation Fig. 6. In this figure it will be noticed that on the second subtracting operation in which the complementary amount 9880 is added to 045635 that there is a carry-over by the usual carry-over devices in the dividend accumulator to the extreme left hand column of 1. This figure 1 represents the quotient up to this point. Upon the next subtraction there is a further carry-over giving 2 in the extreme left hand column of the dividend accumulator and so on. Attention is directed, however, to the fifth entry. On this fifth entry the dividend accumulator goes through or back or zero. There is accordingly a 9 in the column of the dividend accumulator immediately to the right of the 3 which is at the extreme left. This 9 is indicated in the typical computation with a prime, 1. e., 9. It is this 9 which is sensed to determine that the accumulator has gone back of zero. It will also be noted that on this entry there is no carry-over to the left,

the 3 remaining as a 3. However, on the following entry where 108, i. e., nine-tenths of the divisor is added into the dividend accumulator in shifted relation it will be noted that there is a carry-over. Accordingly, this carry-over increases the previous 3 to 4 which is the amount of the quotient in the first place. Upon the next subtracting operation the carry-over in the dividend accumulator goes into the-column to the rightof the column in which the 4 stands showing as a 1. If the typical computation is followed down it will be noted that this column progressively increases 1.2, 3, 4, 5, 6, '7 and that on the following computation where 9880 is introduced to bring the accumulator back of zero that a 9 will again appear to the right of the 7. The 9 amount is then sensing control and this causes the introduction of nine-tenths of the divisor into the dividend accumulator in shifted over columnar relation therein. After the. amount of 108 is introduced another 9' appears. There is accordingly a further introduction of 108 which causes the carry-over to change the 7 to 8 which is the amount of the quotient in this particular column.

From the foregoing it will be seen that the quotient amount is introduced into the dividend accumulator by the carry-over divisor of the accumulator itself in the columns to the left of the dividend amount and by referring to the last three typical computations it.wil1 be seen that the quotient ultimately becomes introduced into columns of the dividend accumulator upon which the dividend amount previously stood.

Mechanism for controlling number of quotient places According to the present invention provision is made for pre-setting the machine so that for any given computation within the limits of the capacity of the machine the quotient can be carried out to a pre-set and pre-determined number of places. To illustrate, consider the following computations, assume 8416 to be divided by 4. If this division is carried out 4 will divide into8 and go twice. It will go into 4 in the next column once, it will not go into 1 and it will go into 16, four times. The answer will be 2104, a four place quotient. However, assume that the computation is to be 8416 divided by 9 and that a four place quotient is to be obtained. Under'these conditions the 9 if divided into 8 will not go and accordingly the quotient must be shifted over out of the first position. If the 9 is again divided into 85,'it will go 9 times. The remainder is 31 and 9 will go three times. The next remainder is 46 and 9,will go five times. The following operation relates to a remainder since the dividend has been come pletely divided and the machine will stop andsthe answer will be 935 with a remainder of 1. The mechanism to be described, takes care of both of these conditions, that is, it allows the quotient to be computed to the determined number of places or one less depending upon whether the divisor goes in the first place or not. i

The place limiting mechanism comprises switching mechanism (see Fig. 5). The switching mechanism comprises a series of brush asssemblies generally designated 62, fast to a shaft 63 and positioned by a single knurled wheel 64 fast to the shaft. The brush assemblies cooperate with a number of readout commutators, the readout sections having eight readout or segment spots 62a corresponding to the maximum number of quotient places which may be obtained in this machine. In the instant machine there are thirty-three read-out sections, thirty-two being shown on Fig. 3c of the circuit diagram and an extra one being shown on Fig. 3b of the diagram.

Before a computation is started the knurled knob 64 is turned up to bring a numeral corresponding to the maximum places to which the quotient is to be computed into alignment with an index.

This quotient place mechanism will first be described with the typical computation of Fig. 6, and it. will be assumed that the mechanism is set for a four place quotient. To set the mechanism for a four place quotient, knurled knob 64 will be The underlined numerals are the quotient figures obtained by the preceding stepsof thexcomputation. The 9 in the position to the right of the 1 signifies that the machine has goneback of zero. It will be noted further than four quotient places have been obtained andrthat the machine has gone back of zero. Uponthe next, computation instead of introducing nine-tenths of the divisor into the dividend accumulator in shifted over columnar position therein the mode of operation must be changed to introduce the :.divisor' itself into the dividend accumulator in non-shifted over columnar relation thereinn: Notice the introduction of 1200 in line ,2 of' the computation from the bottom. The purpose "of-this isto obtain-tn final value of the quotient, i e.-,--

and the true value of the remaindenonllr When the machine senses the .9fabove referred to in line 3 from the bottom of the computation of Fig, 6; relay coil 4V (Fig. 31)) becomes energized and is maintained energized by the stick contacts 4V-i. Each of the V relays has further supplementary relay contacts designated (-4 for relay coil 4V which are associated with the quotient place determining mechanism. The purpose of these contacts is to prevent a related relay coil from becoming energized upon the energization of a V coil which is the normal procedure. By preventing 4Y, for example, from becoming energized the column shift will .be suppressed. The circuit will now be traced. ,Upon energization of 4V, contacts 4V4 become closed and ,a circuit is established from line 35 via wire 6,1, through cam contacts CC--8, through relay contacts 4V-4, through brush 62 at position 4, to common strip 65, through relay coil Rand back through a line 68 to the other side of the D. C. line 34. The energization of R establishes a stick circuit to maintain relay R energized through stick contacts R-l and return line 69 back through relay contacts N-2 to line 35. With relay coil R energized relay contacts R-Z are open prior to the time that contacts CC4 close. Accordingly relay coil 4Y will not become energized.

The energization of R will also open relay contacts Rr-3 and prevent the energization of relay coil ZCR at the time cam contacts CC-5 close. Accordingly, relay contacts 2CRI to 5 will remain in non-shifted position and there will be a readout of the dividend amount itself from the DRIV readout by means of emitter i3. This readout of the dividend is from the DRIV readout and is controlled in the following manner. At the time relay coil 4V becomes energized (Fig. 3b) relay contacts 4V-3 (Fig. 3e) allow energization 'of relay coil'W upon closure of cam contacts for emitter I3 from A. C. line 33 and with this emitter in operation the amount of the divisor is 

